Altered expression of the T cell receptor-CD3 complex in systemic lupus erythematosus

SLE T cells may play a key role in autoantibody production in SLE B cells. In addition, accumulating evidence has shown that SLE T cells participate in the attack on target cells or tissues through the overproduction of pro-inflammatory cytokines or an increase in cell-to-cell adhesion. Thus, the functional abnormality of SLE T cells appears to be pivotal to an understanding of SLE pathogenesis. Accumulating evidence suggests that potential defects may reside in the proximal signal transduction around the TCR-CD3 complex. We have demonstrated that the expression of TCR zeta chain is significantly decreased in peripheral blood T cells from SLE patients. To explore the mechanism of defective expression of TCR zeta chain, we examined mRNA of TCR zeta, and found that two alternatively spliced variants such as exon 7 (-) and short 3'-UTR are detected in SLE. We review the possible role of the TCR zeta defects in autoimmunity and discuss how the splicing variants lead to downregulated protein expression of TCR zeta chain.     

ALTERED EXPRESSION OF THE T CELL RECEPTOR-CD3 COMPLEX IN SYSTEMIC LUPUS ERYTHEMATOSUS

SLE T cells may play a key role in autoantibody production in SLE B cells. In addition, accumulating evidence has shown that SLE T cells participate in the attack on target cells or tissues through the overproduction of pro-inflammatory cytokines or an increase in cell-to-cell adhesion. Thus, the functional abnormality of SLE T cells appears to be pivotal to an understanding of SLE pathogenesis. Accumulating evidence suggests that potential defects may reside in the proximal signal transduction around the TCR-CD3 complex. We have demonstrated that the expression of TCR ζ chain is significantly decreased in peripheral blood T cells from SLE patients. To explore the mechanism of defective expression of TCR ζ chain, we examined mRNA of TCR ζ, and found that two alternatively spliced variants such as exon 7 (-) and short 3'-UTR are detected in SLE. We review the possible role of the TCR ζ defects in autoimmunity and discuss how the splicing variants lead to downregulated protein expression of TCR ζ chain.     

Defect in TCR-CD3zeta signaling mediates T cell hypo-responsiveness in mesenteric lymph node

Mesenteric lymph node (MLN) in gut-associated lymphoid tissue plays obligatory roles in the induction of oral tolerance and ignorance to commensals. However, little is known about its immunological characteristics. In this study, we investigated the hypo-responsiveness of MLN CD4(+) T cells, comparing them with spleen CD4(+) T cells. MLN CD4(+) T cells were hypo-proliferative and expressed low levels of Th1-type cytokines in response to antigen or CD3/T cell receptor (TCR) stimulation. The hypo-responsiveness of MLN CD4(+) T cells is linked neither with changes in the regulatory T cell population (CD4(+)CD25(+), CD4(+)Foxp3(+)) nor the apoptotic population. Rather, MLN CD4(+) T cells showed deformity of T cell:APC conjugation and reduced expression of TCR signaling molecules such as CD3zeta, PLC-gamma1, PKC-theta, Zap70, with reduced phosphorylation of immunoreceptor tyrosine-based activation motifs (ITAMs). Among the alterations in TCR signaling molecules, defective CD3zeta expression is the most evident, and reversal of the anergic state by CD3/CD28 costimulation restored CD3zeta expression levels. Collectively, we suggest that reduced CD3zeta expression and defects in TCR signaling mediate the anergy state of MLN CD4(+) T cells, which play a critical role in maintenance of mucosal tolerance in gut-associated lymphoid tissue.     

Defective expression and tyrosine phosphorylation of the T cell receptor zeta chain in peripheral blood T cells from systemic lupus erythematosus patients

We have reported that tyrosine phosphorylation and expression of the T cell receptor zeta chain (TCR ζ) was decreased in two systemic lupus erythematosus (SLE) patients with an abnormal TCR ζ lacking exon‐7. To examine further the TCR ζ defect and any possible relationship with specific clinical features, we studied the expression of TCR ζ in peripheral blood T cells from 44 patients with SLE, 53 with other rheumatic diseases (30 rheumatoid arthritis (RA), 11 systemic sclerosis (SSc) and 12 primary Sjögren's syndrome(SjS)) and 39 healthy individuals. Flow cytometric analysis demonstrated a significant decrease in the expression of TCR ζ in SLE (P < 0·001), but not in the other rheumatic diseases. Immunoprecipitation experiments confirmed that the expression of TCR ζ in SLE T cells was decreased dramatically (normal: 111·4 ± 22·6%, SLE: 51·6 ± 37·4%, P < 0·0001). The decrease in TCR ζ did not correlate with disease activity, or with the dose of prednisolone (PSL). There were, however, three SLE patients in whom the level of TCR ζ expression normalized after treatment, suggesting that mechanisms responsible for the TCR ζ defect appear to be heterogeneous. These results confirm the defective expression and altered tyrosine phosphorylation of TCR ζ in a large proportion of SLE patients, suggesting that it may play an important role in T cell dysfunction in SLE.     

Attempt to correct abnormal signal transduction in T lymphocytes from systemic lupus erythematosus patients

Systemic lupus erythematosus (SLE) is an autoimmune disease, which predominantly affects females, and causes multiple organ dysfunctions. Recent studies have revealed the underlying immunological abnormalities, especially in lymphocytes from SLE patients. T lymphocytes from SLE patients present abnormalities in T cell receptor (TCR) signaling, for example, decreased expression of TCR zeta chain, PKC theta, and NF-kB p65, decreased PKC dependent protein phosphorylation, impaired translocation of NF-kB p65, decreased production of IL-2 etc. Recently, it is known that reconstitution of deficient TCR zeta chain in T lymphocytes from SLE patients leads to restoration of impaired IL-2 production upon CD3/CD28 stimulation. This time, analysis of abnormal TCR signaling in SLE patients and attempt to correct the impaired IL-2 production by replenishing missing signaling molecules are to be discussed.     

Development of T cells expressing an altered TCR complex

Normal mouse T cells may express alternative TCR complexes containing the FcepsilonR gamma chain (FcRgamma) rather than the zeta homodimer that is present in conventional TCR complexes. While these T cells could play critical roles in regulating immunity, the role of alternative TCR complexes and their requirement for signaling molecules in T cell development remains unknown. We show thatexpression of an FcRgamma transgene in zeta chain-deficient mice (FcRgammaTG, zetaKO mice) reduced the percentage and number of CD4(+) T cells present in these animals, when compared to C57BL/6 mice. Further studies of FcRgammaTG, zetaKO mice expressing the DO11.10 TCR (DOTCR) transgene showed that, when compared to mice expressing conventional TCR complexes, the development of CD4(+), DOTCR(+) thymocytes was altered in mice of different MHC backgrounds and required the presence of zeta-associated protein (ZAP)-70 and lck kinases. The CD4(+), DOTCR(+) T cells bearing alternative TCR complexes have impaired Ca(2+) flux and proliferative response to stimulation. Altogether, these results suggest that the altered development of CD4(+) T cells is not due to qualitative differences in TCR-mediated signals, but more consistent with the hypothesis that it is due to reduced signaling strength mediated through the FcRgamma chain containing only one immunoreceptor tyrosine-based activation motif.     

A chimeric T cell receptor with super-signaling properties

A key question yet to be resolved concerns the structure and function relationship of the TCR complex. How does antigen recognition by the TCR-alphabeta chains result in the activation of distinct signal transduction pathways by the CD3-gammadeltaepsilon/zeta complex? To investigate which part of the TCR-beta chain is involved in TCR signaling, we exchanged different domains of the constant regions of the TCR-beta chain with the corresponding TCR-gamma chain domains. We show here that hybridoma cells expressing a chimeric TCR-beta chain (betaIII) containing intracellular and transmembrane TCR-gamma amino acids, together with a wild-type TCR-alpha (alphawt) chain, were 10 times more sensitive to antigenic stimulation compared to cells expressing TCR-alphawt/betawt chains. This super-signaling phenotype of the betaIII chain was observed in two different TCRs. One specific for an alloantigen (I-A(bm12)) and one for an autoantigen (I-A(b)/MOG(35-55)). We found that this chimeric alphawt/betaIII TCR had normal association with CD3-gammadeltaepsilon and zeta chains. To investigate the effect of the chimeric betaIII chain in transgenic T cells, we made MOG(35-55)-specific TCR transgenic mice expressing either the alphawt/betawt or chimeric alphawt/betaIII TCR. Similar to what was observed in hybridoma cells, transgenic alphawt/betaIII T cells showed a super-signaling phenotype upon antigenic stimulation. Further studies may help us understand the effect of increased TCR signaling on autoimmunity and may lead to the identification of signaling molecules that can be targeted to stop the progression of autoimmune disorders such as multiple sclerosis.     

Proximal signaling control of human effector CD4 T cell function

The functional coupling of T cell receptor (TCR)-mediated signaling events in primary human T cells remains undefined. We demonstrate here that alterations in the expression of proximal TCR-coupled signaling subunits are associated with distinct effector capacities in differentiated human CD4 T cells. Analysis of proximal signaling profiles using biochemical and single cell approaches reveals decreased CD3zeta and ZAP-70 expression correlating with functional anergy, with increased CD3zeta/ ZAP-70 expression and phosphorylation connoting acquisition of effector capacity. By contrast, the FcRgamma signaling subunit known to be expressed in human effector cells and in T cells from the autoimmune disease SLE is up-regulated upon activation, yet does not correlate with functional capacity in effector cells, and does not alter signaling or function in primary FcRgamma transfectants. Our results have implications for targeting signaling molecules in immunotherapy and evaluating the functional consequence of signaling alterations associated with autoimmunity and chronic diseases.     

Increased association of CD38 with lipid rafts in T cells from patients with systemic lupus erythematosus and in activated normal T cells

In this study we have determined whether there is a relationship between CD38 expression on T cells, its distribution in different membrane microdomains, and T cell activation in SLE patients. The data show that CD38 expression is augmented in ex vivo CD3+, CD4+, CD8+, and CD25+ SLE T cells, which correlates with its increased insolubility in Brij 98 detergent, and its translocation into lipid rafts. Moreover, SLE T cells show an altered CD4:CD8 ratio, which is due to a decreased proportion of CD4+ T cells and a concomitant increase in the proportion of CD8+ T cells. These data are consistent with the increased CD38 expression and lipid raft formation, and the significant reduction in the CD4:CD8 ratio observed in mitogen-stimulated normal T cells as compared with that in ex vivo untouched normal T cells. Increased expression of CD38 in floating rafts from SLE T cells, or from activated normal T cells may modulate TCR signaling by providing or sequestering signaling molecules to the engaged TCR.     

RhoH GTPase recruits and activates Zap70 required for T cell receptor signaling and thymocyte development

RhoH is a hematopoietic-specific, GTPase-deficient member of the Rho GTPase family with unknown physiological function. Here we demonstrate that Rhoh-/- mice have impaired T cell receptor (TCR)-mediated thymocyte selection and maturation, resulting in T cell deficiency. RhoH deficiency resulted in defective CD3zeta phosphorylation, impaired translocation of the signaling molecule Zap70 to the immunological synapse and reduced activation of Zap70-mediated signaling in thymic and peripheral T cells. Proteomic analyses demonstrated that RhoH is a component of TCR signaling and is required for recruitment of Zap70 to the TCR through interaction with RhoH noncanonical immunoreceptor tyrosine-based activation motifs (ITAMs). In vivo reconstitution studies also demonstrated that RhoH function depends on phosphorylation of the RhoH ITAMs. These findings suggest that RhoH is a critical regulator of thymocyte development and TCR signaling by mediating recruitment and activation of Zap70.     

Obligatory cross-talk with the tyrosine kinases assembled with the TCR/CD3 complex in CD4 signal transduction.

Dissection of the CD4 signal transduction pathway has revealed striking similarities with the TCR/CD3 pathway. Furthermore, downstream signaling by CD4 is impaired in cells lacking surface TCR, suggesting a role for the TCR/CD3 complex in CD4 signal transduction. We have investigated the molecular basis for the dependence of CD4 signaling on TCR/CD3 expression. Using the phosphotyrosine binding domains of the Shc adaptor and the Fyn kinase, which both participate in CD4 signaling, as baits, we show that CD4 induces tyrosine phosphorylation of a subset of the proteins phosphorylated in response to TCR/CD3 engagement. The phosphoprotein patterns were dramatically altered in cells defective for TCR/CD3 expression, and were recoverable by reconstitution of correctly assembled TCR, suggesting that CD4 uses TCR/CD3-associated tyrosine kinases to signal. Among the tyrosine kinases associated with the resting TCR/CD3 complex, only Fyn is activated following CD4 engagement. The failure of Fyn to become phosphorylated in cells defective for TCR expression underlines the unique role of TCR/CD3 associated Fyn in CD4 signal transduction. While no calcium mobilization was measurable in cells defective for TCR/CD3 expression in response to CD4 engagement, the Ras/MAP kinase pathway could be partially activated. Thus, CD4 activates at least two signaling pathways, and tyrosine kinases associated with the TCR/CD3 complex are key components of one of these pathways.     

CD4+ T cell survival is not directly linked to self-MHC-induced TCR signaling

T cell receptor (TCR) signaling triggered by recognition of self-major histocompatibility complex (MHC) ligands has been proposed to maintain the viability of na?ve T cells and to provoke their proliferation in T cell-deficient hosts. Consistent with this, the partially phosphorylated state of TCR zeta chains in na?ve CD4+ and CD8+ T cells in vivo was found to be actively maintained by TCR interactions with specific peptide-containing MHC molecules. TCR ligand-dependent phosphorylation of TCR zeta was lost within one day of cell transfer into MHC-deficient hosts, yet the survival of transferred CD4+ lymphocytes was the same in recipients with or without MHC class II expression for one month. Thus, despite clear evidence for TCR signaling in nonactivated na?ve T cells, these data argue against the concept that such signaling plays a predominant role in determining lymphocyte lifespan.     

A lysosomal protein negatively regulates surface T cell antigen receptor expression by promoting CD3zeta-chain degradation

Modulation of surface T cell antigen receptor (TCR) expression is an important mechanism for the regulation of immune responses and the prevention of T cell hyperactivation and autoimmunity. The TCR is rapidly internalized after antigen stimulation and then degraded in lysosomes. However, few of the molecules involved in this process have been identified. We demonstrate that the lysosomal protein LAPTM5 negatively regulated surface TCR expression by specifically interacting with the invariant signal-transducing CD3zeta chain and promoting its degradation without affecting other CD3 proteins, CD3epsilon, CD3delta, or CD3gamma. TCR downmodulation required the polyproline-tyrosine motifs and the ubiquitin-interacting motif of LAPTM5. LAPTM5 deficiency resulted in elevated TCR expression on both CD4(+)CD8(+) thymocytes and spleen T cells after CD3 stimulation, as well as enhanced T cell responses in vitro and in vivo. These results identify a lysosomal protein important for CD3zeta degradation and illustrate a unique mechanism for the control of surface TCR expression and T cell activation.     

Altered proximal T cell receptor (TCR) signaling in human CD4+CD25+ regulatory T cells

CD4+CD25+ regulatory T cells play an important role in peripheral tolerance. Upon T cell receptor (TCR)-mediated activation, the cells fail to proliferate but are induced to have a suppressor function. The intracellular signaling events that lead to their responses have not been elucidated. In this study, we have examined the proximal TCR signaling events in freshly isolated human CD4+CD25+ regulatory T cells after TCR ligation. In contrast to CD4+CD25- T cells, TCR ligation of CD4+CD25+ regulatory T cells by anti-CD3 cross-linking resulted in a lower calcium influx and extracellular signal-regulated kinase 1/2 phosphorylation. Examination of the CD3zeta chain phosphorylation status indicated that CD4+CD25+ regulatory T cells have poor phosphorylation of the protein and consequently, reduced recruitment of zeta-associated protein-70 to the TCR immunoreceptor tyrosine motif. The adaptor protein, Src homology 2 domain-containing leukocyte phosphoprotein of 76 kDa, which relays signals to downstream signaling components, also showed reduced phosphorylation, which correlated with reduced VAV guanine nucleotide exchange factors association. Consistent with other findings, the defect is accompanied with impaired actin cap formation, implicating a failure of actin remodeling of the cells. Together, our results demonstrate that CD4+CD25+ regulatory T cells have altered TCR proximal signaling pathways, which could be critical for inducing the distinct behavior of these cells.     

T cell receptor-associated protein tyrosine kinases: The dynamics of tolerance regulation by phosphorylation and its role in systemic lupus erythematosus

There are different abnormalities that lead to the autoreactive phenotype in T cells from systemic lupus erythematosus (SLE) patients. Proximal signaling, involving the T-cell receptor (TCR) and its associated protein tyrosine kinases (PTKs), is significantly affected in SLE. This ultimately leads to aberrant responses, which include enhanced tyrosine phosphorylation and calcium release, as well as decreased IL-2 secretion. Lck, ZAP70 and Syk, which are PTKs with a major role in proximal signaling, all present abnormal functioning that contributes to an altered T cell response in these patients. A number of other molecules, especially regulatory proteins, are also involved. This review will focus on the PTKs that participate in proximal signaling, with specific emphasis on their relevance in maintaining peripheral tolerance, their abnormalities in SLE and how these contribute to an altered T cell response.